RU41944U1 - ROOM PROTECTION SYSTEM FROM UNAUTHORIZED INTERRUPTION OF ACOUSTIC SPEECH INFORMATION (OPTIONS) - Google Patents

Abstract

The utility model relates to means of creating artificial interference, in particular, acoustic and vibro-acoustic interference and can be used to protect the premises from unauthorized interception of acoustic speech information. The protection system comprises a noise generator with a power supply and at least one vibration transducer installed in the room, electrically connected to the generator. In this case, according to the first embodiment, the generator contains an analog noise source, as well as vibroacoustic and acoustic channels for generating a noise signal, and according to the second embodiment, the generator contains three independent paths, each of which contains an analog noise source, as well as vibroacoustic and acoustic channels for generating noise signal. Each vibro-acoustic channel includes a band-pass filter connected to a noise source, an adjustable five-band equalizer with center frequencies of octave filters from 250 to 4000 Hz, a level control, and a power amplifier of the vibro-acoustic channel, with at least one vibration transducer connected to its output. Each acoustic channel contains a band-pass filter connected to a noise source, connected through the first and second level controllers to the first and second power amplifiers of the acoustic channel, respectively. In addition, the system comprises at least one acoustic emitter connected to the output of one of the acoustic channel power amplifiers. The result is a comprehensive protection of selected rooms with a minimum level of "spurious" noise.

Description

The utility model relates to means of creating artificial interference, in particular, acoustic and vibro-acoustic interference and can be used to protect the premises from unauthorized interception of acoustic speech information.

Currently, the protection of voice information is one of the most important tasks in the overall package of measures to ensure information security of both state facilities and institutions, and commercial structures.

It is known that confidential voice information distributed during closed negotiations or meetings in rooms specially designated for this purpose can be intercepted by third parties remotely (i.e. without physical presence directly in a dedicated room) through building envelopes (walls, floors , windows) and / or through the elements of engineering systems that exit and / or pass through this room (ventilation duct, heat and water pipes, etc.). It has been established, in particular, that the use of modern technical means of acoustic reconnaissance (portable sound recording devices, electronic stethoscopes, embedded devices with microphone and contact type sensors) ensures the interception of high-quality acoustic (in particular, speech) information circulating in a protected room through building envelopes such as minimum in reinforced concrete structures of buildings after 1-2 floors, through pipelines - through 2-3 floors, and through ventilation ducts - at a distance of 20-30 m. Table of the directional microphones and speakers laser can capture information at all without the presence of third parties in a protected area with

distances from 50 m (in urban conditions through open window openings by means of directional microphones) to 200 m (in urban conditions through window panes by means of optoelectronic information retrieval systems).

To protect the premises from unauthorized interception of voice information, two methods are mainly used - the method of attenuating the actual speech signal (passive protection), or the method of applying masking additive noise interference (active protection) to the speech signal.

Passive protection is provided through various measures aimed at improving the sound insulation of rooms designed for private meetings and negotiations. Such measures include, in particular, the finishing of the enclosing structures of the allocated premises with special sound-absorbing materials, the acoustic blocking of the openings in the allocated room with viscoelastic fillers, the decoupling of engineering systems (pipelines for various purposes) that exit (passing) through the allocated room through centralized systems by installing special pipe breaks vibration inserts, the installation of special window and door blocks, etc. The indicated measures are most it is expedient, as a rule, carried out during the construction and / or reconstruction of the premises, because the changes in the structure of the finished space is usually associated with significant technical difficulties, can lead to significant financial costs, and often simply impossible.

Active protection is based on the use of a set of technical means that ensure the generation and propagation of noise vibro-acoustic vibrations through its enclosing structures and / or acoustic vibrations for various cracks and holes formed in the enclosing structures, as well as in ventilation ducts, smoke exhaust, etc. In this case, an additive superposition of noise signals occurs on the protected acoustic speech signal and the vibrations of the building envelope caused by it, which at certain

“signal to noise” ratios allows you to completely eliminate the unauthorized interception of closed speech information circulating in the room.

One of the simplest active protection systems is disclosed in US patent No. 3567863 (IPC H 04 R 3/00, publ. 02.03.1971). The known system comprises a noise generator, an amplifier connected to the generator, and an acoustic transducer connected to the amplifier, which is proposed to use a conventional acoustic emitter (column). The disadvantages of the known system include the fact that the generator generates cyclic oscillations, the spectrum of which is in the frequency range 30-10000 Hz, which significantly exceeds the required range for masking speech, which in turn is inefficient from an economic point of view due to the technical complexity of forming the most low-frequency part of the spectrum.

There are also known systems for protecting premises from unauthorized interception of acoustic speech information, including a noise generator with a power supply and at least one vibration transducer installed in the room, electrically connected to the generator.

One such system is described in US patent No. 4098370 (IPC N 05 To 5/00, publ. 04.07.1978). The known system provides for the placement of the vibration transducer on the building envelope (on the wall, ceiling, floor) or on the utilities passing through the allocated room, which significantly expands the system's capabilities to counteract various types of acoustic reconnaissance equipment. In addition, in one embodiment of the known system, it is possible to change the amplitude-frequency characteristics of the generated signal depending on the physical properties of the building envelope, which allows you to customize the system to work in a particular room. However, as far as it follows from the description of US patent No. 4098370, in the known system, as in the one described above, the possibility of excessive noise in individual frequency bands is not excluded. In addition, the use of vibration transducers operating

both the noise of the building envelope. and the noise of the internal volume of the allocated room is associated with excessive energy costs, and also leads to the creation of "spurious" acoustic noise in the room. When “spurious” acoustic noise appears, people in the room quickly begin to feel discomfort and are automatically distracted by the source of such noise, which, of course, does not contribute to a fruitful exchange of necessary information.

Another similar system is described in the patent of the Russian Federation for utility model No. 21490 (IPC N 03 K 3/00, publ. 21.01.2002). The differences between this system and the one described in US Pat. No. 4,098,370 are that a speech-like signal generator is used as a noise generator, as well as in the absence of the ability to adjust the amplitude-frequency characteristics of the generated signal. The disadvantages of this system include the presence of excessive noise in individual frequency bands and the possibility of the appearance of “spurious” acoustic noise in the room.

There are also known systems for protecting premises from unauthorized interception of acoustic information, including several noise generators and vibration transducers electrically connected with them.

One of these systems is described in the patent of the Russian Federation for utility model No. 30478 (IPC N 04 K 3/00, publ. 06/27/2003). The known system includes two white noise generators connected by their outputs to an adder, which in turn is connected through an amplifier to vibration transducers installed on the building envelope and on the engineering communications passing through the room. In this case, the vibration transducers are configured to emit a noise masking signal with a power exceeding the protected speech signal by 30-40 dB.

Specified in the known system, an excess of the level of the speech signal by 30-40 dB when installing vibration transducers on thin-walled enclosing structures will lead to the appearance of tangible "spurious" acoustic

noise in the protected room, which can have a negative impact on participants in meetings (negotiations), in particular, cause fatigue. In addition, in the description of the known system, mention is made of the possibility of tuning the spectrum of the generated interference, but it is not disclosed how this can be achieved.

Of all the above-described systems for protecting premises from unauthorized interception of acoustic speech information, the closest to the claimed utility model (to all its variants) is the system known from US patent No. 4098370.

The objective of the present utility model is the creation of a system that provides comprehensive protection for allocated rooms from unauthorized interception of acoustic speech information circulating in a selected room, and is characterized by the ability to adjust the spectrum of the generated noise and the minimum level of “spurious” noise.

This problem is solved in that in a room protection system from unauthorized interception of acoustic speech information containing a noise generator with a power supply and at least one vibration transducer installed in the room, electrically connected to a generator, according to the first embodiment of the utility model, the noise generator comprises source of analog noise with the normal probability density distribution of instantaneous values, as well as vibroacoustic and acoustic noise generation channels moreover, the vibro-acoustic channel includes a band-pass filter to form a uniform spectrum of the noise signal, the input of which is connected to the output of the noise source, and the output to the input of an adjustable five-band equalizer with center frequencies of octave filters from 250 to 4000 Hz, the output of which is connected to the input of the power amplifier of the vibro-acoustic channel, the output of which is connected to the specified at least one vibration transducer, and the acoustic channel contains a band-pass filter for forming noise signal with a decrease in the frequency response of 6 dB / oct in

the high-frequency side, the input of which is connected to the output of the noise source, and the output through the first and second level controls is connected to the inputs of the first and second power amplifiers of the acoustic channel, and the system contains at least one acoustic emitter connected to the output of one from power amplifiers of the acoustic channel.

The use in the inventive system of at least one acoustic emitter connected through a level control and a corresponding power amplifier with the output of a bandpass filter of the acoustic channel, in combination with using at least one vibration transducer connected through its own level control and a corresponding power amplifier with an output of adjustable a five-band equalizer with the above center frequencies of the octave bands allows you to effectively counteract all types of tools interception of acoustic information while reducing the energy cost of generating interference and helps to reduce the level of "spurious" noise in the protected room. The achievement of this result is due to the following circumstances.

As already mentioned above, the use of vibration transducers known in the prior art makes it possible to effectively counteract the means of intercepting information through vibro-acoustic and optoelectronic channels through floors, enclosing structures, and elements of engineering systems.

The use of at least one acoustic emitter connected to an adjustable output can reduce the power of the vibration transducers, which positively affects the energy costs and the level of “spurious” noise in the room. In this case, the connection of the acoustic emitter through an amplifier with a band-pass filter of the specified type (generating a noise signal with a decrease in the frequency response by 6 dB / oct towards higher frequencies) allows us to obtain broadband acoustic noise of the speech-like spectrum with independent level control, which provides more opportunities

to configure the system depending on the characteristics of a particular dedicated room. The connection of at least one acoustic emitter with independent adjustment provided for in the system provides effective protection of the room from interception of information through the direct acoustic channel in several directions at once (for example, through a door frame and a ventilation system).

The use in the claimed system of an adjustable equalizer and its relationship with vibration transducers (at least one) allows for independent tuning of the amplitude-frequency characteristics of noise signals distributed over the building envelopes and / or elements of engineering systems, depending on the structural and acoustic features of the room, providing Thus, better protection of speech information circulating in the room. The use of a five-octave equalizer with the indicated center frequencies of the adjustment bands is due to the fact, as the results of the corresponding calculations according to the approved method show, an error in calculating speech intelligibility for five octave bands, for example, when calculating with respect to seven octave bands (one band below 90-175 Hz and one band above 5600-11200 Hz) does not exceed 1-2% for uniform in the studied frequency band and “pink” noise, which can be compared with the probability of an error that does not go beyond the statistical th error. The use of more than five adjustment bands is also impractical for economic reasons, since it leads to complication and appreciation of the system without any significant increase in the effectiveness of masking speech information.

It is preferable to use a special semiconductor noise diode as an analog noise source. Such diodes are well known in the art and are one of the simplest and most affordable noise sources, as a result of which the use of such a diode simplifies and reduces the cost of the system design.

For the above reasons, it is also preferable that the shaping filter has a passband of 175-5600 Hz. Despite the fact that the spectrum of sound frequencies extends from 16 Hz to 20,000 Hz, masking the speech signal in the specified range, which is localized experimentally, is the most appropriate. Expansion of the indicated frequency range towards higher frequencies and / or towards lower frequencies is unjustified for economic reasons, since the rise in the cost of the system when expanding the range does not lead to a noticeable increase in its efficiency.

As a vibration transducer, it is preferable to use a piezoelectric transducer made with the possibility of its installation on the enclosing structures of the room or on window glass or on the elements of equipment of engineering systems passing through the room. The use of piezoelectric transducers is due to the fact that they are now widely used, which ensures ease of manufacture and ease of use of the system, as well as the fact that they allow one to obtain a vibrational noise signal whose spectrum is sufficiently close to the spectrum of the generated electrical noise signal .

The claimed problem can also be solved by the fact that in the system of protection against unauthorized interception of acoustic speech information, comprising a noise generator with a power supply and vibration transducers installed in the room, electrically connected to a noise generator, according to the second embodiment of the utility model, the noise generator contains three independent generation paths and generating a noise signal, each of which includes an analog noise source with a normal distribution of probability density of instantaneous values as well as vibroacoustic and acoustic channels for generating a noise signal, and the vibroacoustic channel includes a bandpass filter to form a uniform spectrum of the noise signal, the input of which is connected to the output of the noise source, and the output to the input of an adjustable five-band equalizer with center frequencies of octave filters from 250 to 4000 Hz the output of which is connected through the level control to the input of the vibroacoustic power amplifier

channel, the output of which is connected to at least one vibration transducer, and the acoustic channel contains a bandpass filter for generating a noise signal with a frequency response decrease of 6 dB / oct towards high frequencies, the input of which is connected to the output of the noise source, and the output through the first and second level controllers is connected to the inputs of the first and second amplifiers of the acoustic channel power, respectively, and the system contains at least three acoustic emitters, each of which is connected to the output of one of the power amplifiers from one acoustic channel generating paths and forming a noise signal.

The system, made in accordance with the second option, allows you to get the same technical result as the system according to the first option - effectively counteract all types of means of intercepting acoustic information while reducing the energy cost of generating interference and the level of “spurious” noise in the room. An additional advantage of the second version of the system is that the presence of six channels for generating and generating acoustic signals with independent level control provides a more effective counteraction to interception means.

As in the first embodiment of the utility model, preferred are:

- the implementation of each source of analog noise in the form of a semiconductor noise diode;

- the implementation of each filter of the acoustic and vibro-acoustic channels in each path with a passband of 175-5600 Hz;

- the implementation of each vibration transducer in the form of a piezoelectric transducer with the possibility of its installation on the building envelope or on window glass or on the elements of engineering systems passing through the room.

The utility model will be described below on specific examples of its implementation, which in no way limit the scope of claims, but are given

only for a better understanding of its essence. In this case, links will be made to the accompanying drawings, which depict:

- figure 1 is a system of protection against unauthorized interception of acoustic information circulating in a protected room, made according to the first embodiment;

- figure 2 is a system made according to the second embodiment.

In accordance with the first embodiment, the protection system includes a noise generator, structurally made in a single unit, containing an analog noise source 1 with a normal distribution law of the density of instantaneous values, the operation of which is based on the well-known phenomenon of avalanche breakdown of the pn junction of the noise diode, and the output of the noise source connected to the input of the forming filter 2 of the vibro-acoustic channel, as well as to the input of the forming filter 7 of the acoustic channel, each of which has a passband 17 5-5600 Hz. In this case, the filter 2 of the vibro-acoustic channel generates a signal with a uniform spectrum at the output, and the filter of the acoustic channel 7 forms a signal with a decrease in the amplitude-frequency characteristic by 6 dB / oct towards high frequencies.

The generator also contains a five-band adjustable equalizer 3 with center frequencies of octave bands 250 Hz, 500 Hz, 1000 Hz, 2000 Hz and 4000 Hz, which is connected by its input to the output of the shaping filter 2 of the vibro-acoustic channel, and through its output through the level controller 4 it is connected to the input of the amplifier 5, having at least one output in the form of a connector in the generator housing for cable connection of at least one piezoelectric transducer 6. The number of vibration transducers 6 simultaneously connected to the generator can vary depending on the design features of the protected premises, as well as depending on the radius of action of each converter. As a rule, in a room not equipped with passive protection, at the same time use from 6 to 25 vibration transducers 6. At the same time, with sufficient sound insulation of building envelopes and engineering

systems can only be used vibration transducers 6, installed, for example, on window glass in quantities determined by the design of the window glass.

Adjustment of the equalizer 3 can be carried out, in particular, by means of adjusting knobs displayed on the generator housing (not shown), although one skilled in the art understands that the adjustment means can be performed in any known manner (in the form of buttons, faders, etc.).

The output of the acoustic channel forming filter 7 through the first 8 and second 8a level controllers is connected to the inputs of the first 9 and second 9a of the acoustic channel power amplifiers, each of which has at least one output configured to electrically connect with at least one acoustic emitter (in particular, figure 1 shows two emitters -10 and 10a) through a connector in the housing of the generator. Although the exact number of connected acoustic emitters 10-10a is also determined individually by a specialist for each particular room, it is advisable to provide for the possibility of connecting up to 8 acoustic emitters 10-10 when manufacturing the system.

For the convenience of adjusting the noise signal level by means of knobs 4, 8, and 8a, it is advisable to equip the latter with appropriate means (knobs, buttons, faders, etc.) that are output to the generator housing.

According to the second embodiment of the utility model shown in figure 2, the noise generator, structurally made in a single unit, has three independent paths for generating and generating an acoustic signal, which contain:

(a) analog noise sources 11-13, similar to the described noise source 1, made on semiconductor noise diodes;

(b) shaping filters 21-23 and shaping filters 71-73 connected to respective noise sources 11-13, similar to the described filters 2 and 7;

(c) five-band adjustable equalizers 31-33, similar to the described equalizer 3, each of which is connected by its input to the output of the corresponding filter 21-23, and the output through the corresponding level control 41-43 is connected to the corresponding power amplifier 51-53, each of which has at least one output made in the form of a connector on the generator housing with the possibility of cable connection of piezoelectric transducers 61-63;

(d) amplifiers 91-93 and 91a-93a, the input of each of which is connected through the corresponding level controller 81-83 and 81a-83a to the output of the corresponding shaping filter 71-73, and each of which has at least one output, made from a connector on the generator housing with the possibility of cable connection of acoustic emitters 101-103 and 101a-103a (speakers), the total number of which, depending on the task, can vary from 1 to 24.

As in the first embodiment of the utility model, the equalizers 31-33 and the noise level can be adjusted using the controls 41-43, as well as 81-83 and 81a-83a, by means of appropriate means (knobs, buttons, faders, etc.) .) brought to the generator housing.

The generator in both the first and second embodiment of the system also contains a power supply (111 in FIG. 1 and 110 in FIG. 2, respectively).

Protection of the premises from unauthorized interception of information is as follows.

Before installing the system in a room, potentially vulnerable areas are identified through which information can be intercepted. Identification of vulnerable areas is carried out by assessing the sound insulation of building envelopes, door and window openings, as well as elements of engineering systems passing through a dedicated room. To assess sound insulation, a well-known method can be applied, according to which the difference in sound pressure on the surface of building envelopes (openings and elements) is determined

engineering systems) inside a dedicated room and at points that are located outside the room and theoretically can be used to intercept information.

After that, a noise generator is installed in the room, and piezoelectric transducers 6 (or 61-63 according to the second embodiment of the utility model) are installed on potentially vulnerable building envelopes, door and window openings, and also on pipelines passing through the room) and connected to the noise generator by means of electric cables. At the same time, to protect the enclosing structures, transducers 6 (61-63) are fixed on the protected surface using screw connections (to protect window openings, transducers 6 (61-63) are glued to the window glass; if a double-glazed frame is used, then the transducers are glued to the inner the surface of the inner glass relative to the room), and the transducers 6 (61-63) are attached to pipelines with specially made brackets. When installing transducers 6 (61-63), it is necessary to take into account their radius of action, and also take into account the fact that fixing transducers 6 (61-63) at distances corresponding to the maximum radius of action of the transducer for the material of this enclosing surface in most cases leads to the occurrence of sufficiently audible "spurious" acoustic noise in the protected room. In this regard, it is advisable to use a larger number of converters operating at reduced power, and installed from each other at smaller distances.

To prevent information interception through a direct acoustic channel near potentially hazardous areas (in particular, near through holes in the walls, openings of the ventilation system and / or inside ventilation ducts), acoustic emitters 10-10a (101-103 and / or 101a-103a) are installed, which are also connected to the noise generator via cables.

After installation of the system, it is set up. During the indoor setup process, it can be established at the point of intended exchange of information,

at least one source of test acoustic signal. When the test signal source is working, the protection system is activated and the intelligibility (verbal) of the speech signal is evaluated at potential interception points, adjusting, if necessary, the range of vibro-acoustic noise and / or the level of acoustic noise. It is advisable to assess intelligibility both without the use of technical means and with their use (for example, using directional microphones, accelerometers, etc.). Upon reaching an acceptable signal-to-noise ratio, which provides, along with the necessary level of masking of the speech signal, a comfortable level of extraneous noise inside the room, the adjustment is stopped.

The protection system is included when confidential negotiations or meetings are held indoors. In this case, the source 1 (respectively, according to the second embodiment, each source 11-13) generates a broadband analog noise, which is transmitted to the input of the forming filters 2 (21-23) and 7 (71-73).

From the output of filter 2 (21-23), a noise signal having a uniform spectrum in the range of 175 Hz-5600 Hz is fed to the input of equalizer 3 (31-33), where a predetermined spectrum of the noise signal is generated, which then passes through a level 4 controller (41- 43) and an amplifier 5 (51-53) to the input of the piezoelectric transducers 6 (61-63), which, due to the piezoelectric effect, convert the signals arriving at them into vibrations, as a result of which sound waves propagate through building envelopes and utilities, preventing the interception of information on vibroacoustic channel. When transducers 6 (61-63) are installed on window panes, vibrations occur on the latter, preventing the interception of speech information circulating in the room via an optoelectronic channel.

At the output of filter 7 (71-73), a noise signal is formed with a decrease in the amplitude-frequency characteristic by 6 dB / oct towards higher frequencies, which through the first 8 (81-83) and second 8a (81a-83a) level controls the input of the corresponding power amplifiers 9 (91-93) and 9a (91a-93a), from where it comes

to the inputs of acoustic emitters 10 and 10a (101-103 and 101a-103a, respectively). Acoustic emitters 10 and 10a (101-103 and 101a-103a) converts the incoming electrical signal into acoustic broadband noise with a speech-like spectrum, making it difficult to intercept on a direct acoustic channel. Taking into account the simultaneous use of vibration transducers 6 (61-63), the room is comprehensively protected from interception of acoustic speech information, while independent adjustment of the noise signal level via both vibroacoustic and acoustic channels of the generator minimizes “spurious” noise in the room and ensures the comfort of those in a dedicated room of people.

It should be noted once again that the examples of the implementation of the utility model do not exhaust all possible options for its implementation. In particular, instead of piezoelectric vibration transducers, it is possible to successfully use electromagnetic transducers known from the prior art with corresponding conversion devices at the output of power amplifiers. In addition, various options are available for adjusting the equalizer and level controls - from mechanical to remote by means of an optical infrared or radio channel. All of these options, obvious to the specialist, should be considered within the scope of the claims determined by the attached formula of the utility model.

Claims (10)

1. A system for protecting a room from unauthorized interception of acoustic speech information, comprising a noise generator with a power supply and at least one vibration transducer installed in the room, electrically connected to a generator, characterized in that the noise generator contains an analog noise source with a normal instantaneous probability density distribution values, as well as vibroacoustic and acoustic channels for generating a noise signal, and the vibroacoustic channel includes a band-pass filter for the formation of a uniform spectrum of the noise signal, the input of which is connected to the output of the noise source, and the output - to the input of an adjustable five-band equalizer with center frequencies of octave filters from 250 to 4000 Hz, the output of which is connected through the level regulator to the input of the power amplifier of the vibroacoustic channel, with the output of which said at least one vibration transducer is connected, and the acoustic channel contains a band-pass filter for generating a noise signal with a decrease in the frequency response of 6 dB / oct per hundred high frequencies, the input of which is connected to the output of the noise source, and the output through the first and second level controls is connected to the inputs of the first and second amplifiers of the acoustic channel power, and the system contains at least one acoustic emitter connected to the output of one of the amplifiers acoustic channel power. 2. The system according to claim 1, characterized in that a semiconductor noise diode is used as an analog noise source. 3. The system according to claim 1 or 2, characterized in that the band-pass filters of the acoustic and vibro-acoustic channels have a passband of 175-5600 Hz. 4. The system according to claim 1 or 2, characterized in that a piezoelectric transducer is used as a vibration transducer, made with the possibility of its installation on the building envelope, or on glass, or on utilities passing through the room. 5. The system according to claim 3, characterized in that a piezoelectric transducer is used as a vibration transducer, made with the possibility of its installation on the building envelope, or on window glass, or on utilities passing through the room. 6. A system for protecting a room from unauthorized interception of acoustic speech information, comprising a noise generator with a power supply and vibration transducers installed in the room, electrically connected to a noise generator, characterized in that the noise generator contains three independent paths for generating and generating a noise signal, each of which includes an analog noise source with the normal law of probability density distribution of instantaneous values, as well as vibroacoustic and acoustic channels are formed I of the noise signal, and the vibro-acoustic channel includes a band-pass filter to form a uniform spectrum of the noise signal, the input of which is connected to the output of the noise source, and the output to the input of an adjustable five-band equalizer with center frequencies of octave filters from 250 to 4000 Hz, the output of which is connected through the level control with the input of the power amplifier of the vibro-acoustic channel, with the output of which at least one vibration transducer is connected, and the acoustic channel contains a band-pass filter for forming a smart signal with a decrease in the frequency response by 6 dB / oct towards high frequencies, the input of which is connected to the output of the noise source, and the output through the first and second level controls is connected to the inputs of the first and second power amplifiers of the acoustic channel, and the system contains at least three acoustic emitters, each of which is connected to the output of one of the power amplifiers of the acoustic channel of one of the paths for generating and generating a noise signal. 7. The system according to claim 6, characterized in that each source of analog noise is a semiconductor noise diode. 8. The system according to claim 6 or 7, characterized in that each band-pass filter of the acoustic and vibro-acoustic channels in each of the paths for generating and generating a noise signal has a passband of 175-5600 Hz. 9. The system according to claim 6 or 7, characterized in that each vibration transducer is a piezoelectric transducer made with the possibility of its installation on the building envelope, or on window glass, or on utilities passing through the room. 10. The system according to claim 8, characterized in that each vibration transducer is a piezoelectric transducer configured to be installed on the building envelope, or on window glass, or on utilities passing through the room.